WO2007090597A1 - Method for monitoring and/or controlling or regulating the voltage of at least one cell group in a cellular composite of an energy accumulator - Google Patents

Abstract

The invention relates to the monitoring and/or control or regulation of the voltage of at least one cell group in a cellular composite of an energy accumulator, in particular an energy accumulator in a vehicle power supply system. The invention is characterized in that a data communication between a central logic and a cellular composite logic is carried out via a rail-line connecting them, voltage levels existing between an on-voltage level or an idle voltage level, superior to a maximum voltage level until which the logic of the cell groups exchanges energy with the rail-line for charging and discharging the cell group, and a data level being superior to the idle level.

Description

 Method for monitoring and / or controlling or regulating the voltage of at least one cell group in a cell network of a

energy storage

The invention relates to a method for monitoring and / or controlling or regulating the voltage of at least one cell group in a cell network of an energy store, which consists of a series connection of the individual cells of the energy store, wherein a single cell may consist of a cell or cells connected in parallel. In particular, the invention relates to a cell network of an energy storage in a motor vehicle electrical system, according to the preamble of claim 1. Further, the invention relates to a cell group logic for monitoring and / or control or regulation of the voltage of at least one cell group in a cell network of a Energy storage, in particular an energy storage in a motor vehicle electrical system, according to the preamble of claim 9 and a central logic for monitoring and / or control or regulation of the voltage of at least one cell group in a cell network of an energy storage via a cell group logic, in particular an energy storage in a motor vehicle electrical system, according to the preamble of claim 13.

In the automotive sector, more and more energy storage devices constructed from single cells are being used, preferably energy storage devices constructed from double-layer capacitors. These

Double-layer capacitors have the advantage of providing and storing energy that they can provide high power in the short term. To put on in a motor vehicle necessary supply voltage to come, the individual double-layer capacitors must be connected in series. The cells connected in series thus form a cell network. For charging, for balancing the cell voltage, for detecting under- and overvoltage of individual cells, for maintaining the charge of the cells in standby mode, for loading and unloading or reloading between the individual cells as well as for the diagnosis / monitoring of the individual cells, individual cells or Cell groups are connected to respective cell group logics that can extract or supply energy to a connected rail line to charge or discharge the individual cells or cell groups. It will be described below that each cell group logic is connected to a cell group to monitor and / or control its voltage. The term cell group includes individual cells, so that the case is also described in which a cell group logic is shot at each individual cell of a cell network of an energy store in order to monitor and / or control or regulate its voltage.

So that the cell voltages of the individual cells or cell groups do not diverge during cyclical charging or discharging, it is known to monitor the cell group logics by means of a higher-level control device, namely a central logic, and to control them so that a uniform charging and / or discharging is reached, whereby a long life of the individual cells and thus the entire cell network can be achieved. The cell group logics are usually connected via a data line with the central logic, so that a data communication to ensure the described function can take place. However, this data line leads to an increased wiring complexity and consequently also to an increased susceptibility to errors. In order to reduce the wiring complexity and the susceptibility to errors, a very wide variety of methods are known in the field of motor vehicles, in particular to transmit data via existing supply lines. In general, data to be transmitted between electronic devices is modulated onto the supply voltage lines for this purpose. However, such a procedure is unsuitable due to the resulting voltage swing, especially in the area of monitoring the voltage of individual cells on a cell network, since this distorts measurement results or reference voltage levels impressed on the supply lines which serve to charge or discharge the cell groups or individual cells.

DE 197 33 866 A1 describes an improved method and system for transmitting data in a motor vehicle, in which a satellite station is supplied with power by a central station via a data transmission line used in common for data transmission and power supply. Here, the data transfer does not lead to a readjustment of a power generator, so that the average voltage on the data transmission line (open circuit voltage) is not changed. However, since the data signals to be transmitted are also simply superimposed on the quiescent voltage of the data transmission line in the form of current pulses, which lead to strong, and thus receiver easily detectable voltage pulses, even at small size due to the high (output) resistance of the power generator, on the receiving side can be easily reliably demodulated by a comparator or a window comparator, there is also no possibility here, for data transmission and power supply used to perform a power supply, which simultaneously defines a reference voltage level.

Thus, by means of the existing methods and devices for data transmission on supply lines, no reliable monitoring and / or control or regulation of the voltage of individual cells in a cell network of an energy store, in particular an energy store in a motor vehicle electrical system can be performed, wherein the voltage is determined for each cell group and the cell group is charged and / or discharged in response to the detected voltage, wherein each cell group is connected to cell group logic and determines cell group voltage across each cell group and in cell group logic with one on a DC voltage line Mass is applied to the target voltage and the cell group is charged and / or discharged in dependence on the difference between the determined cell group voltage and the target voltage via the DC voltage line, since the desired voltage due to the data transmission would be falsified.

The object of the invention is to specify an improved method for monitoring and / or controlling or regulating the voltage of at least one cell group in a cell network of an energy store, in particular an energy store in a motor vehicle electrical system, in which data communication via the supply line of the cell group logics (Rail line) can take place. Furthermore, it is the object of the invention to specify a suitable cell group logic and a suitable central logic for this purpose. This object is achieved by a method according to claim 1, a cell group logic according to claim 9 and a central logic according to claim 13. Advantageous developments are the subject matters of the dependent claims.

The inventive method for monitoring and / or controlling or regulating the voltage of at least one cell group in a cell network of an energy storage, in particular an energy storage in a motor vehicle electrical system, wherein the cell group via a supply line, via which the cell group is charged or discharged, with a cell groups Logic, which monitors and / or controls the voltage of the cell group, extracts or supplies energy to cell group logic for charging or discharging the cell group of a rail line, and communication between the cell group logic and another cell group logic and / or a central logic via the rail line is characterized in that a data communication with Spannungspegein between at or above a maximum voltage level, to which the cell group logic with the rail line for charging or discharging the cell group exchanges energy, lying idle levels and a em above the idle level data level is performed.

The cell group logic according to the invention for monitoring and / or controlling or regulating the voltage of at least one cell group in a cell network of an energy store, in particular one

Energy storage in a motor vehicle electrical system, wherein the cell group is connected via a supply line via which the cell group is charged or discharged, with the cell group logic that monitors and / or controls the voltage of the cell group, the Cell group logic for charging or discharging the cell group of a rail conducts energy or supplies, and a communication of the cell group logic and another cell group logic and / or a central logic via the rail line is characterized by a voltage comparator unit outputting data communication via the rail line when power levels on the rail line between one at or above a maximum voltage level up to which the cell group logic exchanges power with the rail line for charging or discharging the cell group, lying idle level and a lying above the idle level data level.

The central logic according to the invention for monitoring and / or controlling or regulating the voltage of at least one cell group in a cell network of an energy storage via a cell group logic, in particular an energy storage in a motor vehicle electrical system, wherein the cell group via a supply line, loaded via the cell group or is connected to the cell group logic that monitors and / or controls the voltage of the cell group, the cell group logic for charging or discharging the cell group of a rail line draws energy and supplies and communication between the cell group logic and another cell group logic and / or the central logic via the rail line, is characterized by a voltage converter unit, which performs data communication via the rail line by voltage level between a on or above the rail line Maximum voltage level, up to which the cell gr uppen logic with the rail line for charging or discharging the cell group energy exchanges, lying idle level and a lying above the idle level data level can be impressed. The cell group mentioned is either a single cell or a composite of several individual cells, wherein the number of cells in the cell group is smaller in each case than the entire cell network. For reasons of cost and effort, it makes sense to combine several cells in a cell group and to determine the data for a cell group instead of for each individual cell. The cells are advantageously double-layer capacitors. However, the method, the cell group logic and the central logic are also suitable for any other type of single-cell energy storage. The cell group logic is advantageously a unit which, in addition to the voltage comparator unit, also has a control unit for charging and / or discharging the cell or cell group. The voltage applied to the cell or cell group can be determined directly in the cell group logic or in the central logic. The voltage control or regulation of the cells advantageously serves both to maintain charge and to balance the voltage of the individual cells. In the cell group logic and central logic embodiments described above, the central logic may transfer commands to the cell group logic in data communication because the central logic can imprint certain voltage levels on the rail line and the cell group logic can memorize the cell group logic Can detect voltage level of the rail line. If a bidirectional data communication is desired, of course, in the cell group logic, a voltage converter unit for impressing certain voltage levels and in the central logic also a voltage comparator unit for detecting voltage levels can be provided. The method according to the invention, the cell group logic according to the invention and the central logic according to the invention thus offer the advantage over the known prior art that the rail line is also supplied to the cell group logic with a reference voltage via which the cell group logic is also fed as can be used for data communication between the central logic and the cell group logic without disturbing the reference voltage. According to the invention, this takes place in that the data communication takes place with voltage levels which are above a maximum voltage level, up to which the cell group logic exchanges energy with the rail line for charging or discharging the cell group, ie, to which the rail line is to " Transfer "of the reference voltage is used. When the maximum voltage level is exceeded, the cell group logic no longer exchanges energy with the rail line for charging or discharging the cell group connected thereto, and the voltage applied to the rail line no longer serves as a reference voltage for charging or discharging the cell groups or individual cells. ie, the supply line via which the cell group is connected to the cell group logic is in any case disconnected from the rail line. As a result, the charging or discharging of the cell group is performed with an unadulterated reference voltage, and in the data communication, the charging or discharging of the cell group is interrupted to preclude erroneous charging or discharging.

Advantageously, the cell group logic is switched active if a rail voltage is applied to the rail line which is above an enable voltage level below the maximum voltage level. The cell group logic is therefore advantageously designed such that the voltage comparator unit actively switches the cell group logic, if a rail voltage is applied to the rail line which is above an enable voltage level below the maximum voltage level. The central logic accordingly advantageously comprises a control unit which drives the voltage conversion unit to impress a rail voltage which is above an enable voltage level below the maximum voltage level in order to activate the cell group logic. In this advantageous embodiment, the cell group logics are forcibly switched to passive, ie, disabled, in the event of a "short to ground" fault. In this way, destruction or damage to the individual cell groups is prevented.

Advantageously, according to the invention, the supply line of the cell group is connected to the rail line such that a power is transmitted between them, which is at or above a first power level, when the rail voltage is above the enable voltage level or above the enable voltage level Low voltage level and below a higher high voltage level or even higher maximum voltage level.

Further advantageously, according to the invention, the supply line of the cell group is connected to the rail line such that a power is transmitted between them which is at or above a second power level above the first power level, if a cell group voltage is above the enable voltage level and below of the low voltage level or above the high voltage level and below the maximum voltage level. According to the invention, the supply lines of different cell groups are advantageously connected to the rail line in such a way that power is transferred between the different cell groups and / or power is taken from or delivered to the rail line.

For this power transmission between the cell groups or at least one cell group and the rail line, the cell group logic according to the invention advantageously has a switch unit which is controlled by the voltage comparator unit and can connect the supply line of the cell group to the rail line such that a certain power wherein the voltage comparator unit determines the extraction or supply of energy from or to the rail line based on certain voltage levels existing on the rail line and a cell group voltage. In the case of the central logic according to the invention, the voltage control unit advantageously controls the voltage converter unit for impressing a rail voltage which is above the enable voltage level in order to control the cell group logic, to connect the supply lines of different cell groups to the rail line Power is transmitted between the different groups of cells and / or power is taken from or delivered to the rail line.

These functions can be used both to balance the cell voltages and to detect under- and overvoltages of individual cells. It is also possible to maintain the charge of the cells in stand-by mode, to charge and discharge or transfer between the individual cells and to diagnose / monitor the individual cells. In the case of unidirectional data communication between the central logic and the cell group logic (s), for example, an instruction to a particular cell group logic may be made by the central logic to connect the supply line of the connected cell group to the rail line at the same time the other cell group logics are instructed to separate the supply lines of the respective cell groups from the rail line. In this case, a targeted charging as well as a targeted discharging of the cell group connected to the rail line can take place via the rail line. In this case, since the central logic can determine the extraction of energy from the rail line or the supply of energy to the rail line, it can also make a targeted diagnosis of a single group of cells in terms of their voltage, resistance and their Capacity. In the case of bidirectional communication between central logic and cell group logic (s), such a diagnosis can also be made by the cell group logic (s), whereby the information transmission can take place via the bidirectional communication mechanism.

According to the invention, the data communication advantageously comprises address, command, data, security and / or response. The data and / or the response further advantageously comprise the internal resistance, the capacitance, the temperature and / or the voltage of a cell group. According to the invention, the data communication advantageously takes place via a binary coding, an amplitude coding, a pulse length coding and / or an amplitude-pulse-length coding.

Advantageously, the inventive control unit controls the voltage converter unit, the data communication between the Perform cell group logic and the central logic via the rail line.

Further details, advantages and features of the present invention will become apparent from the following description of exemplary embodiments with reference to the drawing. Show it:

Fig. 1 shows a preferred embodiment of a device for

Carrying out the method according to the invention,

2 shows a preferred embodiment of the coding of the information according to the invention,

3 shows a preferred embodiment of the function according to the invention of the Enabelns,

4 shows a preferred embodiment of the inventive function of balancing the cell voltages,

5 shows a preferred embodiment of the inventive function of detecting under- and overvoltage,

Fig. 6 shows a preferred embodiment of the invention

Communication function

Fig. 7 shows a preferred embodiment of the invention

Data coding in the inventive

Communication function, and Fig. 8 shows a preferred embodiment of the data encoding in the communication function according to the invention.

1 shows a preferred embodiment of the physical-technical embodiment of the apparatus for performing the method according to the invention is shown. The device is implemented, for example, in a vehicle, not shown here. In FIG. 1, a plurality of cells C1, C2,..., Cn are connected in series in a cell network Z. The cell network Z is connected to the energy electrical system E of the vehicle and is used to provide energy, especially in hybrid vehicles. The cells C1 to Cn are advantageously double-layer capacitors. Each cell C1 to Cn of the cell group Z is connected to a respective cell group logic ZGL1, ZGL2, ..., ZGLn.

In Fig. 1, the device is designed such that each cell C1 to Cn forms a cell group which is connected to its own cell group logic. The cell group logics ZGL1, ZGL2,..., ZGLn are connected to a rail line R, which has a conductor 1 for energy / data and a ground conductor 2. The rail line R is connected to a higher-level central logic ZL, which is also connected to the battery _voltage U _batt , the vehicle _ground and a data bus of the vehicle.

FIG. 2 shows a preferred embodiment of the encoding of the information according to the invention in two variants, the first variant relating to the case illustrated in FIG. 1, that each individual cell C1, C2,..., Cn has its own cell group logic ZGL1, ZGL2 ZGLn is connected and the second variant relates to the case that each cell group logic is connected to a series circuit of several individual cells, so one Cell group not only consists of a single cell, but consists of several individual cells. The difference between the two variants is that in the first variant, a cell voltage is between the enable level and the maximum level, while in the second variant, a cell group voltage is between these levels. For both variants, an enable level lying above the ground level, a low level lying above the enable level, a high level lying above the low level, a maximum level lying above the high level, one above the maximum Level idle level and a data level above the idle level. At a voltage level on the rail line between the ground level and the enable level, the cell group logics are disabled, ie, off. Above the enable level, they are enabled, ie activated. In variant 1, between the enable level and the maximum level, the cell voltage and, in variant 2, the cell group voltage are controlled or regulated by means of a reference voltage impressed on the rail line. Between the maximum level and the idle level, the cell group logics in both variants are switched to neutral and data transfer takes place above the idle level. Low level and high level are used to detect under- and overvoltages of individual cells or cell groups.

FIG. 3 shows a preferred embodiment of the active circuit of the cell group logics according to the invention. A cell group logic ZGLx is activated when the impressed on the power / data conductor 1 voltage U _{in is} greater than or equal to the enable level U _ena bie. If this is not the case, the cell group logic ZGLx is switched to passive, ie disabled. In order to carry out this function, the cell group logic ZGLx comprises a voltage comparator unit 3, which controls the voltage U _in applied to the energy / data conductor 1 with the enable signal. Level U _en abie compares. In the event that the impressed on the power / data conductor 1 voltage U _{1n is} greater than or equal to the enable level U _enab i _e , a logic module 4 is activated, ie, enabled.

FIG. 4 shows a preferred embodiment of the function according to the invention for balancing the cell voltages. In addition to the function shown in FIG. 3 and described in connection therewith, the voltage comparator unit 3 monitors whether the voltage U _1n impressed on the energy / data conductor 1 is greater than or equal to the enable level U _en and less than or equal to the maximum level U _max or alternatively greater than or equal to the low level U | _0W and less than or equal to the high level Uh, _g h. If this is the case, then a released from the logic module 4 switch unit 5, here in the form of a DC / DC converter, instructed, a low power P | _OW to the cell group logic ZGLx connected cell Cx deliver, with a cell voltage U _ze ιi _e as the impressed on the power / data conductor 1 input voltage minus the enable level Uen _ab i _e . The symmetrization of the cell voltage takes place in the event that the interface voltage U, _n in a voltage range above the enable level or the low level U | _0W and below the maximum level or the high level U _hιg n moves. The rail voltage reduced by the enable level is at the same time also the cell voltage, alternatively the cell group voltage. In the event that the cell voltage is greater than the rail voltage reduced by the enable level, energy is transferred from the cell Cx into the rail R by means of the DC / DC converter 5. If the cell voltage U _ze ιι _e smaller than the reduced by the enable level rail voltage U, _n , the energy from the rail R is transferred to the cell Cx.

FIG. 5 shows a preferred embodiment of the functions according to the invention for detecting under- and overvoltage. In addition to The function of the cell group logic ZGLx shown in FIG. 4 and checked is whether the cell voltage U _Z eiie greater than or equal to the enable level U _enab i _e and equal to the low level U | _OW or greater than the high level U _hιgh and less than the maximum level is _3x . If this is the case, the switch unit 5 is instructed to supply or remove a high power P _hι g _h from the cell Cx. This serves to rapidly reduce under or overvoltages.

For the detection of undervoltage or overvoltage in the cell / cell group, therefore, a non-constant power curve of the transfer performance of the DC / DC converter 5 over the cell voltage U _ze ιι _{e is} implemented in addition to the diagnostic / monitor function. In the event that the rail voltage Um between enable level U _en at _> ie and low level U | _0W or between high level U _h ιgh and maximum level U _max , either the normal or preferably the higher transfer capacity is requested. Alternatively, instead of the DC / DC converter 5 as a switch unit, a circuit can be implemented which merely impresses the current on the rail line R, without involving a balancing function or only a partial function (eg unilateral / unidirectional balancing).

FIG. 6 shows a preferred embodiment of the communication function according to the invention. In addition to the function shown in FIG. 5 and described in connection therewith, the cell group logic ZGLx comprises a data interpreter 6 which is supplied with the rail voltage U _1n imprinted on the rail line R when it is detected by the voltage comparator unit 3 in that the rail voltage U _{1n is} greater than _or equal to the idle level U, _d i _e . In this case, data is transmitted, which is evaluated by means of the data interpreter 6, whereby this the switch unit 5, ie, here the DC / DC converter, can control.

FIG. 7 shows a preferred embodiment of the principle of the data coding of the communication function according to the invention. For data transmission here 4 data blocks A, B, D and S are sent to the cell group logic (s) ZGL of the central logic ZL, whereupon this is done by a data block R in response. The data blocks sent from the central logic ZL comprise a data block for the address A, a data block for a command B, a data block for data D and a data block for a security function S.

FIG. 8 shows preferred embodiments of the data coding of the communication function according to the invention. In a data frame described from the five data blocks described in connection with FIG. 7, data communication is established by means of the permitted voltage swing, comprising, as described above, address, command, data, security and response. In the example shown, the address has a length of 8 time slots, the command a length of 3 time slots, the data a length of 8 time slots, the security a length of 4 time slots and the response given within the data frame a length of 8 time slots. The answer can be binary, amplitude modulated, pulse width modulated or amplitude and pulse width modulated. If a binary receiver response is implemented, a well-known data protocol can be used, while in the other variants optimized special solutions are implemented.

With the help of the communication mechanism can both a charge retention of the cells in the stationary mode as well as an up and down Unloading or reloading between the individual cells as well as a diagnosis and a monitoring of the individual cells done.

In the case that the charge retention of the cells in the stand mode not by simply applying the target voltage of the cells to the rail line

R takes place, with the mechanism of balancing being active, as in

4 and described in connection with this, a fixed or variable voltage threshold may be associated with its own

Function part can be used. The activation takes place here via the communication mechanism by means of a separate data command.

The charging and discharging or reloading between individual cells can also take place via the function of balancing shown in FIG. 4 and described in connection therewith. Alternatively, an activation by the communication mechanism via a separate data command is also possible here.

The monitoring of the individual cells / groups for the diagnosis / monitoring of the individual cells preferably includes the internal resistance, the cell capacity, the temperature and the voltage. The temperature sensor can be integrated either separately or on the logic. Voltage and temperature can be measured directly while internal resistance and cell capacity must be preprocessed. The transmission of information to the central logic preferably takes place via the communication mechanism. The energy storage interface according to the invention enables a scalability of the functions / logic, a cost-effective connection of various sensors, a standardized, intelligent energy storage cell, a minimization of the external connection technology, a favorable arrangement from EMC point of view and an improved recycling ability.

According to the invention, therefore, to monitor and / or control or regulate the voltage of at least one cell group in a cell network of an energy store, in particular an energy store in a motor vehicle electrical system, a data communication between a central logic and a cell group logic via the rail connecting them. Conduction whereby voltage levels between an idle level at or above a maximum voltage level up to which the cell group logic is exchanging energy with the rail line for charging or discharging the cell group and a data level above the idle level Level exist.

Claims

claims

1. A method for monitoring and / or controlling or regulating the voltage (Uzeiie) at least one cell group (C) in a cell network (Z) of an energy storage, in particular an energy storage in a motor vehicle electrical system, wherein the

Cell group (C) via a supply line (V) via which the cell group (C) is charged or discharged, connected to a cell group logic (ZGL), which monitors the voltage (Uzeiie) of the cell group and / or controls or the cell group logic (ZGL) for loading or unloading the cell group (C) of a rail line (R)

Energy takes or feeds and a communication between the cell group logic (ZGL) and another cell group logic (ZGL) and / or a central logic (ZL) via the rail line (R), characterized in that a data communication with voltage levels between one at or above a maximum

Voltage level (U _max ), up to which the cell group logic (ZGL) with the rail line (R) for charging or discharging the cell group (C) exchanges energy lying idle level (Uj _d ι _e ) and one above the Idle level (Uj _d ι _e ) lying data level is performed.

2. The method according to claim 1, characterized in that the cell group logic (ZGL) is switched active when on the rail line (R) a rail voltage (U _in ) is applied, which is above a below the maximum voltage level ( U _m ax) lying Enable- voltage level (U _enab ie) is.

3. The method according to claim 1 or 2, characterized in that the supply line (V) of the cell group (C) is connected to the rail line (R) that a power is transmitted at or above a first power level (P | _OW ), if the rail Voltage (U _1n ) above the enable voltage level (U _{enab e e} ) or a low voltage level (U | _0W ) above the enable voltage level and below a higher high voltage level (U _h igh) or the even higher maximum voltage level. Voltage level (U _ma χ) is.

4. The method according to claim 3, characterized in that the supply line (V) of the cell group (C) is connected to the rail line (R) that a power is transmitted, which is at or above a second lying above the first power level Power level (P _h jg _h ) is when a cell group voltage

(Uzeiie) is above the enable voltage level (U _ena bie) and below the low voltage level (U | _0W ) or above the high voltage level (U _h igh) and below the maximum voltage level (U _max ).

5. The method according to any one of the preceding claims, characterized in that the supply lines (V) of different cell groups (C) are connected to the rail line (R) that between the different cell groups (C) power is transmitted and / or power taken from the rail line (R) or delivered to this.

6. The method according to any one of the preceding claims, characterized in that the data communication address (A), command (B), data (D), security (S) and / or response (R).

7. The method according to claim 6, characterized in that the data (D) and / or the response (R) the internal resistance, the

Capacity, temperature and / or voltage (Uz _e ii _e ) of a cell group (C) include.

8. The method according to claim 6 or 7, characterized in that the data communication via a binary coding, an amplitude encoding, a pulse length encoding and / or an amplitude-pulse length encoding is carried out.

9. cell group logic (ZGL) for monitoring and / or controlling or regulating the voltage (U _Ze ιi _e ) at least one cell group (C) in a cell network (Z) of an energy storage device, in particular an energy storage in a motor vehicle electrical system, wherein the Cell group (C) via a supply line (V), via which the cell group (C) is charged or discharged, with the cell group logic

(ZGL) which monitors and / or controls the voltage (Uz _e ii _e ) of the cell group (C), the cell group logic (ZGL) for charging or discharging the cell group (C) of a rail line (R ) Extracts or supplies energy and communication between cell group logic (ZGL) and other cell group logic

(ZGL) and / or a central logic (ZL) via the rail line (R), characterized by a voltage comparator unit (3) which performs data communication via the rail line (R) when on the rail line (R) Voltage levels between one at or above a maximum voltage level (U _ma χ), up to which the

Cell group logic (ZGL) with the rail line (R) for charging or discharging the cell group (C) exchanges energy, lying idle level (U _id ι _e ) and above the idle level (U _id ι _e ) lying Data level applied.

10. Cell group logic (ZGL) according to claim 9, characterized in that the voltage comparator unit (3) actively switches the cell group logic (ZGL) if a rail voltage (U _in ) is applied to the rail line (R), above one below the maximum Voltage level (U _ma χ) lying Enable voltage level

(Uenable) Happens.

11. cell group logic (ZGL) according to claim 9 or 10, characterized by a switch unit (5), which is controlled by the voltage comparator unit (3) and the

Supply line (V) of the cell group (C) can connect to the rail line (R) that a certain power is transmitted, wherein the voltage comparator unit (3) the extraction or supply of energy from or to the rail line (R) determined on the basis of certain on the rail line (R) voltage level and based on a cell group voltage (U _Ze ιi _e ).

12. cell group logic (ZGL) according to one of claims 9 to 11, characterized in that the data communication via a binary coding, an amplitude encoding, a pulse length encoding and / or an amplitude-pulse length encoding is carried out.

13. Central logic (ZL) for monitoring and / or controlling or regulating the voltage (U _Ze ιie) at least one cell group (C) in a cell network (Z) of an energy storage via a cell group logic (ZGL), in particular an energy storage in a motor vehicle electrical system, wherein the cell group (C) via a

Supply line (V) via which the cell group (C) is charged or discharged, connected to the cell group logic (ZGL), which monitors and / or controls the voltage of the cell group (C), the cell group logic (ZGL ) for charging or discharging the cell group (C) of a rail line (R) draws or supplies energy and communication between the cell group logic (ZGL) and another cell group logic (ZGL) and / or the central logic (ZL ) via the rail line (R), characterized by a Voltage converter unit which performs data communication via the rail line (R) by applying to the rail line (R) voltage levels between one at or above a maximum voltage level (U _ma χ) up to which the cell group logic (ZGL) with the rail line (R) for loading or unloading the cell group (C)

Energy exchanges, lying idle level (Uj _d ι _e ) and above the idle level (Uj _d ι _e ) lying data level can be impressed.

14. central logic (ZL) according to claim 13, characterized by a control unit which controls the voltage converter unit to impress a rail voltage (U _in ), which is above one below the

Maximum voltage level (U _ma χ) lying Enable-

Voltage level (U _en abie) is to activate the cell group logic (ZGL).

15. Central logic (ZL) according to claim 14, characterized in that the control unit drives the voltage converter unit

Rail voltage (Uj _n ), which is above the Enable voltage level (U _en a _b ie) to control the cell group logic (ZGL), the supply lines (V) of different cell groups (C) so with the rail line (R) that between the different cell groups (C) power is transmitted and / or power from the rail line (R) taken or delivered to this.

16. Central logic unit according to claim 14, characterized in that the control unit controls the voltage converter unit to perform the data communication between the cell group logic (ZGL) and the central logic (ZL) via the rail line (R).

17. Central logic unit according to one of claims 13 to 17, characterized in that the data communication via a binary Coding, an amplitude coding, a pulse length coding and / or an amplitude-pulse-length coding takes place.